Seeder with metering system having selectively powered metering sections

ABSTRACT

A metering system for a seeding machine is provided. The metering system includes selectively powered metering sections operable to individually allow or restrict seed dispensation. A damper arrangement is also provided so that pneumatic conveying of the particulate within the machine is consistently maintained when particulate flow is varied between the metering sections.

CROSS-REFERENCE TO RELATED APPLICATION

The present application claims the benefit of and priority from U.S.Provisional Patent Application Ser. No. 61/444,467, filed Feb. 18, 2011,the entire disclosure of which is hereby incorporated by referenceherein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to seeding machines, includingseeding machines of a pneumatic type that are commonly referred to asseeders and, more particularly, to seeders having selectively poweredmetering sections operable to individually allow or restrict seeddispensation.

2. Discussion of the Prior Art

Those of ordinary skill in the art will appreciate that seeders arecommonly used in the agricultural industry to dispense particulatematerials such as seeds and/or fertilizers into the ground. It is knownin the art of seeding to provide a large, high-capacity cart that istowed by a tractor, along with an implement having a multitude ofground-engaging openers that deposit the seeds and/or fertilizerscarried by the cart. In the case of air seeders, the seeds and/orfertilizers carried by the cart are typically contained within largetanks or hoppers, with each tank dispensing seed into a collectorassembly positioned therebelow. The collector assemblies introduce thestreams of material gravitating from the tanks into pneumatic conveyinglines that deliver the materials to their ultimate destinations.Metering structure may be provided between each tank and the respectivecollector assembly to control the rate at which the material enters thecollector assembly or to restrict entry of the material into thecollector assembly.

SUMMARY

According to one aspect of the present invention, a metering system foruse in a particulate delivery system, wherein the particulate deliverysystem includes a rotatable drive shaft and a tank containingparticulate, is provided. The metering system includes a plurality ofselectively-powered particulate metering sections, each of whichcomprises a rotatable metering roller, a rotatable metering wheel, arotatable engagement wheel, a drive wheel, and a control arm. Themetering roller is configured to receive particulate from the tank andis operable to dispense the particulate when rotated and to preventparticulate dispensation when not rotated. The metering roller isconfigured to rotate with the metering wheel. The engagement wheel isoperable to rotate the metering wheel and thereby the metering rollerwhen the engagement wheel and the metering wheel are drivinglyinterengaged. The drive wheel is configured to be mounted on the driveshaft to rotate therewith. The drive wheel engages the engagement wheel.The control arm shiftably supports the engagement wheel for shiftingmovement into and out of driving engagement with the metering wheel,such that particulate dispensation is prevented by the metering rollerwhen the engagement wheel is drivingly disengaged from the meteringwheel and particulate is dispensed by the metering roller when theengagement wheel is shifted into driving engagement with the meteringwheel.

According to another aspect of the present invention, a particulatedelivery system is provided. The particulate delivery system includes atank containing particulate, a rotatable drive shaft, and a meteringsystem. The metering system includes a plurality of selectively-poweredparticulate metering sections. Each of the metering sections includes arotatable metering roller, a rotatable metering wheel, a rotatableengagement wheel, a drive wheel, and a control arm. The metering rolleris in communication with the tank and is operable to dispense theparticulate when rotated and to prevent particulate dispensation whennot rotated. The metering roller is configured to rotate with themetering wheel. The engagement wheel is operable to rotate the meteringwheel and thereby the metering roller when the engagement wheel and themetering wheel are drivingly interengaged. The drive wheel is mounted onthe drive shaft to rotate therewith. The drive wheel engages theengagement wheel. The control arm shiftably supports the engagementwheel for shifting movement into and out of driving engagement with themetering wheel, such that particulate dispensation is prevented by themetering roller when the engagement wheel is drivingly disengaged fromthe metering wheel and particulate is dispensed by the metering rollerwhen the engagement wheel is shifted into driving engagement with themetering wheel.

According to another aspect of the present invention, a particulatedelivery system is provided. The system comprises a tank containingparticulate, a plurality of particulate-transporting lines, a meteringsystem, an airflow generator, and a plurality of damper assemblies. Themetering system includes a plurality of particulate metering sections.Each of the metering sections is associated with a respective one of theparticulate-transporting lines and includes a metering device configuredto control dispensation of the particulate from the tank to therespective line. The airflow generator is in communication with theparticulate-transporting lines so as to provide pneumatic conveying ofthe particulate within the lines. Each of the damper assemblies isassociated with a respective one of the particulate-transporting linesand is operable to selectively restrict airflow within the respectiveparticulate-transporting line responsive to variations in metering ofparticulate to the respective particulate-transporting line.

Among other things, the presence of a plurality of selectively powered,independently rotatable metering rollers allows for precise control ofthe locations onto or into which seed or other particulate materials aredispensed. In one utilization of such precise control, seeding overlapis avoided even in instances in which the machine itself passes morethan once over a given stretch of ground, through the rapid, selectivestoppage of metering rollers positioned above the given stretch ofground.

This summary is provided to introduce a selection of concepts in asimplified form. These concepts are further described below in thedetailed description of the preferred embodiments. This summary is notintended to identify key features or essential features of the claimedsubject matter, nor is it intended to be used to limit the scope of theclaimed subject matter.

Various other aspects and advantages of the present invention will beapparent from the following detailed description of the preferredembodiments and the accompanying drawing figures.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

A preferred embodiment of the present invention is described in detailbelow with reference to the attached drawing figures, wherein:

FIG. 1 is a right front isometric view of an air seeder incorporatingthe principles of the present invention;

FIG. 2 is an enlarged right front isometric view of a portion of an airseeder similar to that of FIG. 1, particularly illustrating a collectorassembly and metering structure below a tank;

FIG. 3 is an enlarged left front isometric view of the portion of theair seeder seen in FIG. 2, particularly illustrating the transmissionsystem for the metering structure and the mechanism for adjusting theposition of the seed plates;

FIG. 4 is an enlarged, exploded right rear isometric view of the portionof the air seeder seen in FIG. 2, sans the transmission system,particularly illustrating the seed flow directing structures of thelower tank, a plurality of metering sections, and a collector assembly;

FIG. 5 is an enlarged, partially exploded, partially sectioned rightrear isometric view of the portion of the air seeder seen in FIG. 4,particularly illustrating the components of the metering sections;

FIG. 6 is a vertical cross-sectional view of the right side of theportion of the air seeder seen in FIG. 4;

FIG. 7 is an enlarged right front isometric view of the portion of theair seeder seen in FIG. 4, particularly illustrating the components ofthe metering sections;

FIG. 8 is a partially sectioned front elevational view of a collectorassembly, showing the interior thereof and the diverter valves in aposition such that the valves completely close the upper loading zonesand open the lower loading zones;

FIG. 9 is a partially sectioned front elevational view of the collectorassembly of FIG. 8, showing the interior thereof and the diverter valvesin an intermediate position, wherein both upper and lower loading zonesare open so that materials from the overhead tank are introduced intoboth upper and lower air streams passing through the collector assembly;

FIG. 10 is a partially sectioned front elevational view of the collectorassembly of FIGS. 8 and 9, showing the interior thereof and the divertervalves in a position such that the valves force metered product from theoverhead container to drop only into the upper loading zones;

FIG. 11 is a left rear isometric view of a metering section in adisengaged configuration;

FIG. 12 is a vertical cross-sectional view of the left side of themetering section of FIG. 11 in an engaged configuration;

FIG. 13 is a vertical cross-sectional view of the left side of themetering section of FIGS. 11 and 12 in a disengaged configuration;

FIG. 14 is an enlarged, partially sectioned right front isometric viewof a damper as shown in FIG. 1, illustrating both the engaged (dashedlines) and disengaged (solid lines) configurations;

FIG. 15 is a partially sectioned view of the right side of the damper ofFIG. 14 in a disengaged configuration; and

FIG. 16 is a partially sectioned view of the right side of the damper ofFIGS. 14 and 15 in an engaged configuration.

The drawing figures do not limit the present invention to the specificembodiments disclosed and described herein. The drawings are notnecessarily to scale, emphasis instead being placed upon clearlyillustrating the principles of the preferred embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention is susceptible of embodiment in many differentforms. While the drawings illustrate, and the specification describes,certain preferred embodiments of the invention, it is to be understoodthat such disclosure is by way of example only. There is no intent tolimit the principles of the present invention to the particulardisclosed embodiments.

With initial reference to FIG. 1, the illustrated machine comprises anair cart 10 that is adapted to be connected in tandem with a towingtractor (not shown) and a planting implement having multiple openersthereon (not shown). Generally speaking, cart 10 supplies seeds and/orfertilizer to the planting implement as the tractor pulls both machinesin tandem across a field.

The particular air cart 10 selected for purposes of illustration hasthree tanks 12,14,16 included as a part thereof, although this numbermay vary. The tanks 12,14,16 may be used, for example, to separatelycontain seeds, starter fertilizer, and additional fertilizer or granularinoculant for the soil.

Each of the tanks is provided with its own collector assembly 18positioned below the respective tank for introducing materials from thetank into a number of conveying air streams. Such air streams areproduced by a fan 20 at the rear of the cart that delivers air to adistribution manifold 22. Manifold 22, in turn, directs the powerful airstreams into upper and lower primary runs of conveying lines 24 and 26,respectively. The number of upper and lower primary lines 24 and 26,respectively, can vary widely without departing from the scope of thepresent invention. In the present application, however, a total of nineupper primary lines 24 and nine lower primary lines 26 are shown inFIGS. 1 and 8-10, while eight upper primary lines 24 and eight lowerprimary lines 26 are shown in FIGS. 2-4 and 7. (FIGS. 5, 6, and 11-16are generic in this regard.)

Although FIG. 1 illustrates lines 24 and 26 disconnected from themanifold 22, it will be appreciated that, in practice, a section of pipeor hosing extends between such locations to complete each conveyingline. From the front of the air cart 10, conveying lines 24 and 26 arecoupled with flexible hoses (not shown) that lead to the plantingimplement, where appropriate divider structure splits each primarystream into a number of secondary product streams leading to individualopeners of the implement.

As shown in FIG. 2 and others, a metering structure 28, which will bedescribed in depth below, is positioned above each collector assembly18. Each collector assembly 18 comprises a generally hollow body thatincludes a pair of vertically stacked upper and lower collector modules30 and 32, respectively. The body of each module 30,32 is generallyrectangular and is fabricated from a plurality of plate materials topresent a front wall 34, a spaced rear wall 36, and a pair of oppositeend walls 38 and 40. Front wall 34 is provided with out-turned flanges34 a and 34 b; rear wall 36 is provided with out-turned flanges 36 a and36 b; and end walls 38 and 40 are provided with out-turned flanges 38a,38 b and 40 a,40 b, respectively. As best shown in FIG. 4, all of theaforementioned flanges facilitate bolting of collector modules 30, 32 toone another and to the bottom of the metering structure 28.

As illustrated in particular in FIGS. 8-10, the interior of uppercollector module 30 is subdivided by a plurality of upright,transversely spaced collector partitions 42 extending between front wall34 and rear wall 36, there being a total of one fewer such partitions 42than there are upper and lower primary lines 24,26. In FIGS. 8-10, forinstance, eight partitions 42 are present; and the collector partitions42 cooperate with one another and with opposite end walls 38,40 topresent nine separate upper compartments 44 across the width of themodule 30, with the upper compartments 44 being effectively sealed fromone another. Upper compartments 44 directly underlie correspondingoutlets of the metering structure 28 so as to receive ninecorresponding, discharging streams of material from such structure 28.

In the same nine-line embodiment, lower module 32 has a similar seriesof eight upright collector partitions 46 that extend between front andrear walls 34,36 thereof and cooperate with end walls 38,40 to definenine discrete lower compartments 48 in lower module 32. The nine uppercompartments 44 are in direct overhead registration with thecorresponding nine lower compartments 48 so as to effectively definenine generally upright collector passages 50 extending from the uppermargin of upper module 30 to the lower margin of lower module 32, eachsuch collector passage 50 having an upper portion defined by thecorresponding upper compartment 44 and a lower portion defined by thecorresponding lower compartment 48.

Regardless of the number of compartments 44,48 that are present, eachupper compartment 44 is provided with an upper loading zone 52 formed bya transversely J-shaped cup 54 extending between front wall 34 and rearwall 36 thereof. The generally upright leg 56 of cup 54 is locatedapproximately halfway between adjacent collector partitions 42 andterminates at a distance below the top margin of upper module 30. Theconcave leg 58 of each cup 54 likewise extends the entire distancebetween front wall 34 and rear wall 36 and has its distal end welded orotherwise secured to the proximal partition 42 or end wall 38 as thecase may be. Concave leg 58 of each loading cup 54 registers with aninlet 60 in rear wall 36 and an outlet 62 in front wall 34. As shown inFIG. 5 and others, a rear tube 64 comprising part of the upper conveyingline 24 is secured to back wall 36 in registration with inlet 60, whilea front tube 66 is secured to front wall 34 in registered communicationwith outlet 62. Thus, each upper loading zone 52 is disposed within thepath of pressurized air flowing through a corresponding one of the upperprimary conveying lines 24.

Each of the upright collector passages 50 is also provided with a lowerloading zone 68 located in the corresponding lower compartment 48. Inthis respect, a floor 70 extends across the entire width of the body ofcollector assembly 18, and particularly across the bottom of lowermodule 32. The floor 70 includes a transversely U-shaped, invertedchannel 72 having a plurality of cup segments 74,76,78. As illustratedespecially in FIG. 8, for instance, three cup segments 74,76,78 may bebolted to the upper surface of the floor 70, each such segment includingthree separate cups 80,82,84. The length of the line of cup segments 74,76, and 78 is such that when floor 70 is fastened to the bottom marginof lower module 32 by bolts 86,88 and wing nuts 90,92, segments 74, 76,and 78 slip up into lower compartments 48 while channel 72 abuts thebottommost of the flanges of end walls 38 and 40. Although three cupsegments having three cups apiece is a preferred configuration, it iswithin the ambit of the present invention for any suitable number of cupsegments and cups to be used.

Each lower loading zone 68 is in open communication with a rear inlet 94in rear wall 36 and a front outlet 96 in front wall 34. A rear tube 98of the corresponding lower primary line 26 is affixed to rear wall 36 inregistered communication with inlet 94, while a front tube 100 of line26 is affixed to front wall 34 in registered alignment with outlet 96.Each lower loading zone 68 is disposed in the path of travel of the airstream flowing through the corresponding primary line 26 as it passesthrough lower compartment 48. Such air stream thus passes into, through,and out of the lower loading zone 68.

Each upper compartment 44 of the collector passages 50 contains its owndiverter valve 102. Each diverter valve 102 is in the nature of aflapper plate that is substantially the same width in a fore-and-aftdirection as the corresponding upper compartment 44. Each valve 102 isfixed to a fore-and-aft rock shaft 104 that is journaled by front andrear walls 34,36 and is located proximal to the uppermost tip of theJ-shaped cup 54 of upper loading zone 52.

Each valve 102 is moveable between a position completely covering andthus closing off the upper loading zone 52, as shown in FIG. 8, and analternative extreme position, shown in FIG. 10, in which the valve isinclined in the opposite direction to close off the lower loading zone68. More particularly, the FIG. 8 position of valve 102 is such that thelower loading zone 68 is open but the upper loading zone 52 iscompletely closed. The FIG. 10 position of valve 102 is such that theupper loading zone 52 is open but the lower loading zone 68 iscompletely closed. FIG. 9 illustrates the valves 102 in an intermediateposition, wherein both the upper loading zones 52 and the lower zones 68are open.

In order to actuate the diverter valves 102 between their variouspositions, actuating mechanism broadly denoted by the numeral 106 isprovided. In one preferred form of the invention, actuating mechanism106 is designed to operate all of the diverter valves 102simultaneously. More specifically, actuating mechanism 106 includes anoperating lever 108 for each valve 102, such lever 108 being affixed toan outer end of rocker shaft 104 where it projects forwardly beyondfront wall 34. Each lever 108, in turn, has an elongated slot 110 at itsdistal end remote from the point of connection of lever 108 to rockshaft 104.

Mechanism 106 further includes a single push-pull rod 112 that extendsacross the front of the upper collector module 30 adjacent its uppermargin. Further, mechanism 106 includes a series of couplings 114secured to rod 112 at spaced locations along the length thereof. Thecouplings 114 connect the rod 112 with the operating levers 108. Eachcoupling 114 comprises a block 116 that is slidably adjustablypositionable along the length of rod 112 and is secured in a selectedposition by a set screw 118. Further, each coupling 114 includes a pin120 (see FIG. 6) projecting rearwardly from block 116 into the slot 110of the corresponding actuating lever 108. Thus, as rod 112 is pushed orpulled along its length, such motion is transmitted to operating levers108, and the arcuate motion of levers 108 relative to the straight linereciprocal motion of rod 112 is accommodated by virtue of the couplingpins 120 moving between opposite ends of slots 110 in levers 108. Ahandle 122 at one end of rod 112 facilitates manipulation thereof.

A pair of guide brackets 124 and 126 are secured to front wall 34 ofupper collector module 30 adjacent opposite lateral ends thereof andreciprocally support the push-pull rod 112. Rod 112 has a pair ofcross-holes 128 and 130 therein, positioned generally adjacent handle122 and adapted to removably receive a cotter pin 132. Holes 128 and 130are so located that when rod 112 has diverter valves 102 positioned asin FIG. 8, holes 128 and 130 are both located to the left side of guidebracket 126. Thus, as shown in FIG. 7 (which illustrates the samediverter valve 102 position as FIG. 8), the cotter pin 132 may beinserted into hole 130 at such time to bear against the inboard surfaceof guide bracket 126 and prevent rod 112 from being shifted axially tothe right (directions here being from the perspective of one viewing thecited figures), which would shift the diverter valves 102 away fromtheir positions covering the upper loading zone 52. By removing cotterpin 132, rod 112 can be shifted rightwardly from the position of FIGS. 7and 8 until the diverter valves 102 are brought to their positions forcovering lower loading zone 68, as illustrated in FIG. 10. Cotter pin132 may then be inserted into hole 128, which is now located on theoutboard side of guide bracket 126, thus locking rod 112 againstleftward movement and thereby retaining diverter valves 102 in theappropriate position for covering the lower loading zone 68.

As illustrated in FIG. 9, when cotter pin 132 is completely removed fromrod 112, rod 112 may be positioned in an intermediate position, whereindiverter valves 102 open both upper and lower loading zones 52 and 68.Additional holes in rod 112 could be provided to receive cotter pins orthe like on opposite sides of guide bracket 126 to hold diverter valves102 in such intermediate position, if desired. Alternatively, othermeans could be provided for releasably locking rod 112 and divertervalves 102 in such intermediate position.

During operation, air streams from lines 24 and 26 are constantlypassing through the body of each collector assembly 18. Thus, in theillustrated embodiment, all of the upper loading zones 52 and all of thelower loading zones 68 are always exposed to conveying streams of air.If it is desired for product from a selected one of the overhead tanks12,14,16 to be metered into only the lower primary lines 26, therespective push-pull rod 112 is set in the position of FIGS. 7 and 8 soas to cause all of the diverter valves 102 associated with the selectedtank 12, 14, or 16 to close the respective upper loading zones 52 andopen the respective lower loading zones 68. Thus, product gravitatingthrough collector passages 50 lands on the diverter valves 102 and isdirected away from upper loading zones 52 into lower compartment 48 andlower loading zones 68. Upon entering the lower loading zones 68, theproduct is immediately entrained in the air streams passing throughloading zones 68 and conveyed downstream through lower primary lines 26.If the air streams coming into lower loading zones 68 have already beenloaded with materials from an upstream tank, the products gravitatingthrough the collector assembly simply join with the existing materialsand travel together through lower primary lines 26 to their ultimatedestinations.

On the other hand, if the operator desires to have products from aselected one of the overhead tanks 12,14,16 enter only into the upperprimary lines 24, the respective push-pull rod 112 is positioned asshown in FIG. 10 to cause all of the diverter valves 102 associated withthe selected tank 12, 14, or 16 to close their respective lower loadingzones 68 and open their respective upper loading zones 52. Thus, productmetered from the selected tank 12, 14, or 16 gravitates into thecollector passages 50 and is directed by the diverter valves 102directly into upper loading zones 52, where the transversely movingstreams of air entrain the materials and carry them downstream in upperlines 24. If product from an upstream tank has already been introducedinto lower primary lines 26, such product merely passes through lowerloading zones 68 and continues to travel within lower lines 26 withoutbeing combined in any way with the product introduced into upper lines24 at the upper loading zones 52.

If, for any reason, the operator prefers to have product from a selectedone of the overhead tanks 12,14,16 entering both upper lines 24 andlower lines 26, the respective push-pull rod 112 is positioned in theintermediate position of FIG. 9, wherein diverter valves 102 associatedwith the selected tank 12, 14, or 16 are positioned to open therespective upper loading zones 52 as well as the respective lowerloading zones 68 at the same time. Different degrees of openness of theupper and lower loading zones can also be achieved by positioningcontrol rod 112 at any selected one of a number of positions tocorrespondingly vary the relative amounts of product to flowing intozones 52 and 68.

It will thus be seen that the collector assembly 18 of the presentinvention provides a great deal of flexibility and convenience for thefarmer. Various combinations of tanks and supply lines can be used tobest suit the farmer's particular needs at any given time. For example,the cart 10 shown in FIG. 1 has three tanks 12, 14, and 16, each ofwhich is provided with its own collector assembly 18. In one exemplaryuse of this construction, rear tank 12 may be filled with fertilizer,center tank 14 may contain seeds, and front tank 16 may containadditional fertilizer or an inoculant. In a preferred particulatediversion arrangement, the collector assembly 18 associated with reartank 12 may then be set so that all materials from tank 12 bypass theupper loading zones 52 and drop into lower loading zones 68 for pickupby the lower primary lines 26. The collector assembly 18 of middle tank14 may be set to close its lower loading zones 68 so that all materialsfrom tank 14 are diverted into only the upper zones 52, where they arepicked up by the air streams within upper primary lines 24. Thus,fertilizer from rear tank 12 and seeds from middle tank 14 aremaintained separate from one another. Meanwhile, the collector assemblyfor the front tank 16 may be set to drop product into either or both ofthe primary lines 24 and 26 as may be desired, depending upon the natureof the products within the front tank 16.

In other situations it may be desirable, for example, to use all threetanks 12,14,16 for the same product. All three tanks 12,14,16 may befilled with seeds, for example. By first cleaning out the tanks 12,14,16completely (the means by which this can be efficiently accomplishedbeing described hereinbelow), tanks that have previously been used forfertilizer may now be used for seeds, and vice versa.

In a preferred embodiment, each of the tanks 12, 14, and 16 includes astorage portion 134 and an outlet portion 136 that is positioned belowthe storage portion 134 and coupled thereto. The outlet portion 136 isin vertical alignment with the respective metering structure 28. Theoutlet portion 136 preferably includes a rear wall 138, a pair of sidewalls 140 and 142, an inner front wall 144, and an outer front wall 146.

The inner and outer front walls 144 and 146, respectively, are spacedfrom each other so as to form a channel 148 therebetween. A pair ofopenings or windows 150 are formed in the outer front wall 146 such thatthe windows 150 are in communication with the channel 148. A removablewindow cover 152 is provided for covering each window 150. The innerfront wall 144 includes a pair of openings 154 that are also incommunication with the channel 148. A tube or hose 156 extends into theinterior of the respective tank 12, 14, or 16 from each of the openings154 such that each tube 156 is in communication with the channel 148 atone end and with the interior of the tank 12, 14, or 16 at the otherend. The channel 148 is in communication at its lower end with therespective metering structure 28, as will be discussed in more detailhereinbelow. The aforementioned structures thus form a pressureequalization system that ensures that the internal pressure in the giventank 12, 14, or 16 is the same as that in the metering structure 28.Such balancing of pressure helps prevent hang-up or “bridging” of theparticulate within the metering structure 28.

Preferably, each outlet portion 136 includes a variety of structuresdesigned for direction of and control of the particulate materialcontained in the respective tank 12,14, or 16. For instance, each outletportion 136 preferably includes a divider 158 that extends in afore-and-aft direction to bisect the outlet portion 136. However,multiple dividers or none at all could be used.

As best shown in FIGS. 4-6, in a preferred embodiment, the outletportion 136 also includes a roof 160 having a peak 162. Seed or otherparticulate material entering the outlet portion 136 from the storageportion 134 is diverted into either the fore or aft portion of theoutlet portion 136 by the roof 160. A pair of irregular slits 164 a, 164b are formed in the roof 160. Each of the slits 164 a, 164 b is suchthat a portion of the divider 158 projects therethrough.

As best shown in FIG. 7, a plurality of triangular diverters 166 arepreferably provided at the base of the outlet portion 136. Eachtriangular diverter 166 further diverts the seed or particulatematerial, albeit in one lateral direction or another rather than fore oraft as for the roof 160. The material then exits the outlet portion 136via one of a plurality of outlets 168.

In a preferred embodiment, a plurality of sliders 170 are provided ineach outlet portion 136. The sliders 170 are operable to slide towardand away from the center of the outlet portion 136 prior to fixation ina selected position. In the illustrated embodiment, such sliding isinitiated via manual adjustment of rods 172, each of which can be fixedvia wing nuts 174 to ensure the respective slider 170 is held stationarywhen desired. A plurality of end supports 176 are provided to supportthe ends of the sliders 170 and to guide the respective slider 170 in alinear direction when the slider 170 is in motion. In a preferredembodiment, a pair of end supports 176 is provided on each of the sidewalls 140,142. A pair of end supports 176 is also provided on each sideof the divider 158.

The sliders 170 are positioned such that the roof 160 is positionedabove and overhangs the sliders 170. In addition to diverting theproduct, as described above, the roof 160 also ensures that the productdoes not fall between the sliders 170.

The sliders 170 are operable to shut off dispensation of particulatematerial to selected portions of the metering structure 28 or to themetering structure 28 in its entirety. More particularly, when one ofthe rods 172 is pulled outward relative to the outlet portion 136, therespective slider 170 moves from the position shown in FIGS. 2-7, inwhich the associated outlets 168 are unobstructed, to one (not shown) inwhich the slider 170 covers each of the associated outlets 168. Onlymaterial having already entered the portion of the metering structure 28associated with the given slider 170 prior to its closure will then beavailable for dispensation, and no additional material from the tanks12,14,16 will be allowed to enter the respective portion of the meteringstructure 28. The latter effect is particularly advantageous when, forinstance, maintenance or repair is required for components of themetering structure 28, as one or more of the sliders 170 can bepositioned to block particulate from entering the metering structure 28or a portion thereof while work is being done.

Although the sliders 170 may be positioned to leave the outlets 168fully uncovered or fully covered, intermediate positions are possible,as well. Furthermore, each of the sliders 170 may be positioneddifferently from the other sliders 170.

The use of few sliders 170, as shown in the illustrated embodiment,allows for easy isolation of large portions of the metering structure 28or of the metering structure 28 in its entirety for convenientmaintenance and repair access. However, it is noted that any number ofsliders or no sliders at all may be present without departing from thespirit of the present invention.

The illustrated metering structure 28 includes suitable meteringmechanisms for either discharging materials at a metered rate of flowfrom the tanks 12, 14, and 16 into the respective collector assemblies18 or preventing their discharge into the respective collectorassemblies 18. More particularly, metering structure 28 includes aplurality of metering sections 178 (one of which is shown in isolationin FIGS. 11-13), each of which includes, among other things, a rotatabledrive wheel 180 having teeth 180 a, a rotatable engagement wheel 182having teeth 182 a, and a rotatable metering wheel 184 having teeth 184a. A metering roller 186 is connected to rotate with the metering wheel184. Preferably, the metering roller 186 includes a plurality of flutes188, which are arranged in a helical pattern and are configured todefine a plurality of particulate-receiving pockets 190 therebetween.However, a variety of roller configurations are permissible. Forinstance, the flutes could be arranged in a herringbone or other type ofpattern, or a non-fluted roller could be used. Furthermore, with respectto certain aspects of the invention, the metering structure couldalternatively be configured to vary the rate of particulate dispensationrather than just providing “on” and “off” configurations.

In the illustrated embodiment, each of the drive wheels 180 is mountedon a common drive shaft 192 to rotate therewith. However, it is withinthe ambit of the present invention for multiple drive shafts to be used,provided that appropriate drive mechanisms are present.

In a preferred embodiment, the rate of rotation of the drive shaft 192is controlled by a transmission system 194, as shown in FIGS. 2 and 3. Avariety of transmission systems known in the art are suitable forimplementation with the inventive seeder without departing from thespirit of the present invention. For instance, a positive ground drivetransmission having dual- or multi-speed options might be implemented,or a variable drive transmission could be provided. Regardless of theexact implementation, the ability to vary the rotational speed of thedrive shaft 192 is desirable, since such rotational speed control allowsthe metering rate to be independent of tire rotational speed and totherefore be optimized for a variety of particulate materials. Forinstance, a slow speed may be desirable when seeding fine seeds such ascanola or mustard, whereas larger seeds may suitably be dispensed at ahigher rotational speed. In other instances, metering rate variationsmight be desirable based on the soil conditions in a particular locationwithin a field.

Each metering section 178 also includes a control arm 196 pivotallymounted relative to the drive shaft 192 for swinging movement about apivot axis that is aligned with the drive shaft 192. The engagementwheel 182 is rotatably mounted on the upper end of the control arm 196in such a manner that the teeth 182 a of the engagement wheel 182 aremaintained in intermeshed engagement with the teeth 180 a of the drivewheel 180. Rotation of the drive wheel 180 is thus transmitted to theengagement wheel 182. A hydraulic cylinder 198 is mounted at one of itsends to a cantilevered arm 200 and is connected to the lower end of thecontrol arm 196 at the other of its ends. As best shown in FIG. 12, whenthe hydraulic cylinder 198 is retracted, the upper end of the controlarm 196 pivots forward such that the engagement wheel 182 mountedthereon is operable to drivingly engage the metering wheel 184 by meansof the intermeshing of teeth 182 a of the engagement wheel 182 withteeth 184 a of the metering wheel 184, to thereby cause the meteringwheel 184 and, in turn, the metering roller 186, to rotate. As bestshown in FIG. 13, however, when the hydraulic cylinder 198 is extended,the upper end of the control arm pivots backward such that theengagement wheel 182 mounted thereon is not operable to drivingly engagethe metering wheel 184. That is, the teeth 182 a do not intermesh withthe teeth 184 a. Rotation of the metering wheel 184 and, in turn, themetering roller 186, will thereby either cease or fail to be initiated.Seed or particulate material dispensation can therefore quickly andselectively be initiated or stopped for each individual metering section178.

The above-described metering configuration is highly advantageous,providing near-instantaneous stoppage of seed dispensation. In a systemthat attempts stoppage using a moveable gate above a metering roller,for instance, the quantity of seed having already passed by the gate enroute to the roller will still be dispensed after the gate has beenclosed. By contrast, the inventive configuration described herein stopsthe dispensation directly at the roller. Therefore, the only particulatedispensation that will occur after disengagement of the engagement wheeland metering wheel is that due to continued inertial rotation of themetering roller (which is minimal because of the frictional engagementbetween the roller, particulate, and surrounding structure). Stoppage ofdispensation is therefore nearly instantaneous.

Although hydraulic cylinders are used in the preferred embodiment foractuation of the control arms 196, it is noted that a variety ofactuation means fall within the scope of the present invention. Forinstance, pneumatic or spring-based actuation systems might be used.Furthermore, a single actuator could act on more than one meteringsection or on all of the metering sections simultaneously. Ultimately,however, a quick-acting actuating system is desirable.

It is further noted that a mechanism other than a pivoting control armcould be used to enable engagement and disengagement of the engagementand metering wheels. For instance, means could be provided fornon-pivoting fore-and-aft shifting of the engagement wheel or, if theteeth were configured appropriately, the engagement wheel could swinglaterally toward and away from the metering wheel.

Each metering section 178 also includes a pair of vertical meteringpartitions 202,204 that form the sides of an upright metering passage206. The metering partitions 202,204 correspond to and are arranged invertical alignment with the end walls 38,40 and the collector partitions42 found in the collector assembly 18, such that the upright collectorpassages 50 and the upright metering passages 206 are in verticalalignment with each other. More particularly, each metering section 178includes a base plate 208 having an opening 210 and a top plate 212having an opening 214 and an opening 216. Whereas the opening 210connects the metering passage 206 with a respective collector passage50, the opening 214 connects the metering structure with the channel 148so as to allow for pressure equalization between the metering structure28 and the respective tank 12, 14, or 16. The opening 216 is incommunication with a respective one of the outlets 168 of the outletportion 136 of the respective tank 12, 14, or 16.

The wheels 180,182,184 of each metering section 178 are positionedadjacent the metering partition 202 on the side of the partition 202that faces away from the metering partition 204. The metering roller 186is positioned on the other side of the metering partition 202, such thatit is positioned laterally between metering partitions 202,204 or, inother words, within the upright metering passage 206. Slots 218 and 220are formed in metering partitions 202 and 204, respectively, to allowthe drive shaft 192 to pass therethrough.

As best shown in FIG. 11, a variety of particulate guidance structuresare provided to define the upright metering passage 206 or to influencethe flow of particulate material therethrough. More particularly, ashield 222, a seed plate 224, an inlet guide 226, and an outlet guide228 are provided. The shield 222 includes an upper portion 230, a curvedmiddle portion 232, and a lower portion 234. The seed plate 224 includesan arm region 236 and a lip region 238, with the lip region 238 havingan end 240. Particulate material that enters the metering section 78through the opening 216 is guided toward the metering roller by theinlet guide 226, the arm region 236 of the seed plate 224, and the upperportion 230 of the shield 222. The particulate material is then trappedin the pockets 190 of the metering roller 186, such that the material istransported by the metering roller 186 as it rotates in acounter-clockwise direction as viewed in FIG. 11. When the end 240 isreached, however, the material falls downward under the influence ofgravity toward and out of the opening 210 in the base plate 208. Thematerial is guided toward the opening 210 by the lower portion 234 ofthe shield 222, as well as by the outlet guide 228. Any particulatematerial that does not fall from the pockets 190 travels past the end140 until it is enclosed in the pockets 190 by the curved middle portion232 of the shield 222.

The middle portion 232 and the upper portion 230 thus ensure thatparticulate material is not lost out of the back of the respectivemetering section 178.

Each metering section 178 also shares a removable front wall 242, bestshown in FIGS. 2 and 3, that can be attached or removed via wing nuts244. When attached for operation, the front wall 242 ensures thatparticulate material is not lost out of the front of any of the meteringsections 178.

Removal of the front wall 242 provides convenient access to the criticalcomponents of each metering section 178. Although a single shared frontwall 242 is preferred, multiple front walls could be provided, with onewall corresponding to several metering sections 178 or with eachmetering section 178 including its own front wall.

In a preferred embodiment, each of the seed plates 224 is mounted on ashared shaft 246, best shown in FIG. 5, that traverses the uprightmetering passages 206. As shown in FIG. 3, the shaft 246 is connected atone end to a handle 248. The handle 248 includes a projection 250 thatis designed to fit into one of a plurality of slots 252 in a positioningguide 254. Movement of the handle 248 and, in turn, shifting of theprojection 250 from one of the slots 252 to another of the slots 252results in pivoting of the plurality of seed plates 224 from oneposition to another. Thus, the seed plates 224 may be positioned in arange of configurations, from very close proximity to the meteringrollers 186, as shown by the solid line in FIG. 6, to a substantialdistance from the metering rollers 186, as shown by the dashed line inFIG. 6. Such positional control of the seed plates 224 provides theoperator with the ability to further customize the metering process tovarious particulate sizes.

It is noted that a variety of seed plate designs fall within the scopeof the present invention. In addition to basic shape variations, forinstance, modified seed plates might include ridges for additional seedguidance, with the spacing and configuration of the ridges varyingaccording to the seed type.

In a preferred embodiment, each of the metering sections 178 alsoincludes an airflow diverter 256. As best shown in FIGS. 5 and 6, thediverter 256 acts in cooperation with the outer front wall 146 to definea path of travel for air moving between the channel 148 and therepective metering section 178 as part of the pressure-equalizationsystem described previously.

In a preferred embodiment, means are provided for complete and rapidemptying of the contents of the tanks 12, 14, and 16 into the collectorassemblies 18. Under normal operation, as described above, each meteringstructure 28 receives particulate materials gravitating from therespective tank 12, 14, or 16 through respective outlets 168 thereof.The metering rollers 186 then selectively allow or prevent particulatedispensation into a respective collector assembly 18 to proceed.However, such rollers 186 can be intentionally bypassed if and when theoperator wishes to completely and rapidly empty the contents from thetank so that they pass directly into the respective collector assemblies18 instead of being metered slowly or not at all by the metering rollers186. More particularly, when the seed plates 224 are positioned as shownby the dashed line in FIG. 6, seed entering the metering sections 178may completely bypass the respective metering rollers 186 and therebytravel from the respective tank 12, 14, or 16 to the respectivecollector assembly 18 with little or no resistance.

Furthermore, the present design of each collector assembly 18 isconducive to rapid, complete, and easy dumping of the contents of thetanks 12, 14, and 16 after they have traversed the metering sections 178as described above. To facilitate such clean-out, the floor 70 of eachcollector assembly may be quickly and easily removed by simplyunscrewing the wing nuts 90,92 and allowing floor 70 to drop out. Thediverter valves 102 for that particular assembly are then set in theposition of FIG. 8, allowing the contents of the overhead tank to dropstraight through the collector passages 50, bypassing the upper loadingzones 52.

It will also be appreciated that calibration of the metering unit 28 canbe easily achieved in a manner somewhat similar to cleaning out of thetanks 12, 14, and 16. By removing the floor 70 from a particularcollector assembly 18 and replacing it with a calibrating receptacle(not shown), product can be run through each metering section 178 anddischarged into the calibrating receptacle for measurement. Desiredadjustments of the appropriate components of the metering section 178can then be readily carried out.

A variety of systems can be implemented for determining which of thehydraulic cylinders are actuated and when. An operator-based systemwould be permissible, for instance, with the machine operator manuallyflipping switches, pressing buttons, or providing input to a guided userinterface in order to signal the cylinder actuation(s). An automatedsystem could be used, as well. For instance, a system whichautomatically allows or prevents seed dispensation from certain meteringsections based on a known seeding plan and the current position of themachine could be used. In one implementation, this system could be basedon machine coordinates derived from a global navigation satellite system(GNSS) or global positioning system (GPS). Hybrid systems or othervarieties of manual and/or automated systems fall within the scope ofthe present invention, as well. Ultimately, however, a system thatallows for quick signal transmission and resulting engagement ordisengagement of a selected metering roller or rollers is desirable.

In a preferred embodiment, as shown in FIG. 1, a damper assembly 258 maybe added to each upper primary line 24 and lower primary line 26. Thedamper assembly 258 is operable to assist in the balancing of pressureacross the upper primary lines 24 and lower primary lines 26, as will bedescribed below.

As shown in FIG. 1, a fan 20 provides airflow which is distributed tothe lines 24,26 via a distribution manifold 22. When no seed is beingdispensed or when an equal amount of seed is being dispensed througheach metering section 178, the resistance to airflow in each line 24,26will be essentially equal (assuming that the damper assemblies 258 areeach configured identically so as to identically affect the airflow).Thus, the airflow will be distributed essentially equally through thelines 24,26. However, if a selected metering section 178 is deactivatedsuch that no seed is dispensed out of it into a respective collectorassembly 18, the lack of seed flow and, in turn, the lack of airflowobstruction within the respective lines 24,26 will lead to a diversionof airflow away from the remaining partially obstructed (by seed)dispensing lines 24,26 and into the unobstructed non-dispensing lines24,26 (again assuming equivalent damper-based effects). This will resultin less airflow in the dispensing lines 24,26, leading to reducedmaterial-carrying capacity in these lines 24,26 and increased likelihoodor plugs forming in the lines 24,26.

The damper assemblies 258 address this airflow diversion and resultingdeficiency by being activated in coordination with the hydrauliccylinders 198 of the metering sections 178 and, in turn, with thedispensation and stoppage of dispensation of particulate. Moreparticularly, when a hydraulic cylinder 198 is actuated to stop themetering and dispensation of particulate material, the respective damperassembly 258 is actuated to provide a suitable degree of obstruction ofthe respective line 24,26 such that an airflow loss does not occur inthe remaining lines 24,26. In essence, the actuated damper assembly 258acts as a proxy for the non-dispensing seed or particulate material,providing the effect that the seed would have had if it had beendispensed. When a hydraulic cylinder is retracted such that metering anddispensation do occur, however, the damper assembly 258 is configuredsuch that airflow is not obstructed by the damper assembly 258, theairflow instead being appropriately obstructed by the material beingdispensed.

A preferred embodiment of a damper assembly 258 is illustrated in FIGS.14-16. As shown, the damper assembly 258 includes a mounting arm 260, ahydraulic cylinder 262, a rod 264, and a flap 266. One end of thecylinder 262 is mounted on the mounting arm 260, while the other end ofthe cylinder 262 connects to the rod 264. The flap 266 is fixed to theother end of the rod 264 such that a fixed angle is maintained betweenthe rod 264 and the flap 266. The damper assembly 258 also defines astorage region 268. In the retracted cylinder configuration shown inFIG. 15, which corresponds to the (retracted cylinder) engaged meteringconfiguration shown in FIG. 12, the rod 264 is positioned by thecylinder 262 such that the flap 266 is contained in the storage area 268and therefore does not influence the airflow. In the extended cylinderconfiguration shown in FIG. 16, which corresponds to the (extendedcylinder) disengaged metering configuration shown in FIG. 13, the rod264 is positioned by the cylinder 262 such that the flap 266 angles intothe body of the damper assembly 258 to thereby partially obstruct theairflow.

Although a two-position flap 266 may be used, it is also within thescope of the present invention for variable positioning of the flap tobe implemented. Such positioning ability would be particularly desirableif, for instance, the metering structure provides for variableparticulate flow (rather than “on” and “off,” as shown) or ifintroduction of particulate from multiple tanks into a given linenecessitates variable airflow obstruction capability for airflowbalancing to occur. Furthermore, it is within the scope of the presentinvention for a damper to be provided to correspond to each meteringroller, to just those metering rollers associated with a given meteringstructure (as is illustrated in FIG. 1), or to some other subset ofmetering rollers that is deemed appropriate for the particularcircumstance.

In a preferred embodiment, the hydraulic lines (not shown) controllingthe damper assemblies 258 are teed directly off of the respectivehydraulic lines (not shown) controlling the respective metering sections178. Therefore, each damper cylinder 262 is preferably fluidly connectedin series to a respective one of the metering cylinders 198 (bothcorresponding to one of the metering sections 178) so that the cylindersare operated simultaneously. However, a variety of coordinated orindependent control systems could be used in implementing a dampersystem. Furthermore, other airflow restriction means that varystructurally from the damper assemblies 258 described herein could beused without departing from the spirit of the present invention.

Although the damper assembly 258 is described above in the context of amachine having all of the preferred features of the present invention,it is noted that the damper assembly 258 could be implemented in airseeders having a variety of dispensing line and/or meteringconfigurations. For instance, the damper assemblies could be implementedin a seeder having only one set of dispensing lines and making use of ashut-off gate above a metering roller to stop or start dispensation.Ultimately, the damper assemblies 258 are appropriate in anycircumstance in which it is desirable to counteract the airflowimbalance that would occur between individual dispensing lines due to achange in the seed dispensation rate into one or more of them.

The preferred forms of the invention described above are to be used asillustration only and should not be utilized in a limiting sense ininterpreting the scope of the present invention. Obvious modificationsto the exemplary embodiments, as hereinabove set forth, could be readilymade by those skilled in the art without departing from the spirit ofthe present invention.

The inventors hereby state their intent to rely on the Doctrine ofEquivalents to determine and access the reasonably fair scope of thepresent invention as pertains to any apparatus not materially departingfrom but outside the literal scope of the invention set forth in thefollowing claims.

What is claimed is:
 1. A metering system for use in a particulatedelivery system, wherein the particulate delivery system includes arotatable drive shaft and a tank containing particulate, said meteringsystem including a plurality of selectively-powered particulate meteringsections, each of said selectively-powered particulate metering sectionscomprising: a rotatable metering roller configured to receiveparticulate from the tank, said rotatable metering roller operable todispense the particulate when rotated, said rotatable metering rolleroperable to prevent particulate dispensation when not rotated; arotatable metering wheel, said rotatable metering roller beingconfigured to rotate with the rotatable metering wheel; a rotatableengagement wheel operable to rotate the rotatable metering wheel andthereby the rotatable metering roller when the rotatable engagementwheel and the rotatable metering wheel are drivingly interengaged; adrive wheel configured to be mounted on the rotatable drive shaft torotate therewith, said drive wheel engaging the rotatable engagementwheel; and a control arm supporting the rotatable engagement wheel, saidcontrol arm being movable so as to shift the rotatable engagement wheelinto and out of driving engagement with the rotatable metering wheel,such that particulate dispensation is prevented by the rotatablemetering roller when the rotatable engagement wheel is drivinglydisengaged from the rotatable metering wheel and particulate isdispensed by the rotatable metering roller when the rotatable engagementwheel is shifted into driving engagement with the rotatable meteringwheel.
 2. The metering system of claim 1, said rotatable metering rollerincluding a plurality of flutes, said flutes defining a plurality ofparticulate-receiving pockets therebetween.
 3. The metering system ofclaim 2, said flutes being arranged in a helical pattern.
 4. Themetering system of claim 1, said rotatable metering wheel, saidrotatable engagement wheel, and said drive wheel each including aplurality of teeth, said teeth of the rotatable engagement wheel andsaid teeth of the drive wheel being configured to intermesh with eachother, said teeth of the rotatable engagement wheel and said teeth ofthe rotatable metering wheel being configured to intermesh with eachother.
 5. The metering system of claim 4, said teeth of each of therotatable metering wheel, the rotatable engagement wheel, and the drivewheel extending at least generally radially.
 6. The metering system ofclaim 1, said control arm being pivotally mounted for swinging movementabout a pivot axis that is aligned with the rotatable drive shaft, suchthat pivoting of the control arm shifts the rotatable engagement wheelinto and out of driving engagement with the rotatable metering wheelwhile maintaining driving interengagement between the drive wheel andthe rotatable engagement wheel.
 7. The metering system of claim 1, eachof said selectively-powered particulate metering sections furthercomprising a particulate guide configured to direct the flow ofparticulate from the tank.
 8. The metering system of claim 7, saidparticulate guide being shiftable toward and away from the rotatablemetering roller, said particulate guide thereby being configured todirect the particulate toward the rotatable metering roller for meteringor to allow the particulate to bypass the rotatable metering roller forunobstructed dispensation.
 9. The metering system of claim 1, each ofsaid selectively-powered particulate metering sections furthercomprising an actuating mechanism operable to shift the control arm. 10.The metering system of claim 9, said actuating mechanism comprising ahydraulic cylinder.
 11. The metering system of claim 9, said actuatingmechanism being controllable by a manually initiated signal.
 12. Themetering system of claim 9, said actuating mechanism being controllableby an automatically initiated signal.
 13. The metering system of claim9, said automatically initiated signal being initiated based at least inpart on a predetermined dispensation plan and a geospatial coordinate.14. The metering system of claim 1, said selectively-powered particulatemetering sections being individually controllable so that materialdispensation is variable from one selectively-powered particulatemetering section to another.
 15. A particulate delivery systemcomprising: a tank containing particulate; a rotatable drive shaft; anda metering system, said metering system including a plurality ofselectively-powered particulate metering sections, each of saidselectively-powered particulate metering sections including— a rotatablemetering roller in communication with the tank, said rotatable meteringroller operable to dispense the particulate when rotated, said rotatablemetering roller operable to prevent particulate dispensation when notrotated; a rotatable metering wheel, said rotatable metering rollerbeing configured to rotate with the rotatable metering wheel; arotatable engagement wheel operable to rotate the rotatable meteringwheel and thereby the rotatable metering roller when the rotatableengagement wheel and the rotatable metering wheel are drivinglyinterengaged; a drive wheel mounted on the rotatable drive shaft torotate therewith, said drive wheel engaging the rotatable engagementwheel; and a control arm supporting the rotatable engagement wheel, saidcontrol arm being movable so as to shift the rotatable engagement wheelinto and out of driving engagement with the rotatable metering wheel,such that particulate dispensation is prevented by the rotatablemetering roller when the rotatable engagement wheel is drivinglydisengaged from the rotatable metering wheel and particulate isdispensed by the rotatable metering roller when the rotatable engagementwheel is shifted into driving engagement with the rotatable meteringwheel.
 16. The particulate delivery system of claim 15, said rotatablemetering roller including a plurality of flutes, said flutes defining aplurality of particulate-receiving pockets therebetween.
 17. Theparticulate delivery system of claim 16, said flutes being arranged in ahelical pattern.
 18. The particulate delivery system of claim 15, saidrotatable metering wheel, said rotatable engagement wheel, and saiddrive wheel each including a plurality of teeth, said teeth of therotatable engagement wheel and said teeth of the drive wheel beingconfigured to intermesh with each other, said teeth of the rotatableengagement wheel and said teeth of the rotatable metering wheel beingconfigured to intermesh with each other.
 19. The particulate deliverysystem of claim 18, said teeth of each of the rotatable metering wheel,the rotatable engagement wheel, and the drive wheel extending at leastgenerally radially.
 20. The particulate delivery system of claim 15,said control arm being pivotally mounted for swinging movement about apivot axis that is aligned with the rotatable drive shaft, such thatpivoting of the control arm shifts the rotatable engagement wheel intoand out of driving engagement with the rotatable metering wheel whilemaintaining driving interengagement between the drive wheel and therotatable engagement wheel.
 21. The particulate delivery system of claim15, each of said selectively-powered particulate metering sectionsfurther including a particulate guide configured to direct the flow ofparticulate from the tank.
 22. The particulate delivery system of claim21, said particulate guide being shiftable toward and away from therotatable metering roller, said particulate guide thereby beingconfigured to direct the particulate toward the rotatable meteringroller for metering or to allow the particulate to bypass the rotatablemetering roller for unobstructed dispensation.
 23. The particulatedelivery system of claim 15, each of said selectively-poweredparticulate metering sections further including an actuating mechanismoperable to shift the control arm.
 24. The particulate delivery systemof claim 23, said actuating mechanism comprising a hydraulic cylinder.25. The particulate delivery system of claim 23, said actuatingmechanism being activated based on a manually initiated signal.
 26. Theparticulate delivery system of claim 23, said actuating mechanism beingactivated based on an automatically initiated signal.
 27. Theparticulate delivery system of claim 26, said automatically initiatedsignal being initiated based at least in part on a predetermineddispensation plan and a geospatial coordinate.
 28. The particulatedelivery system of claim 23, each of said actuating mechanisms beingindependently activated.
 29. The particulate delivery system of claim23; and a navigation system operable to provide an activation signal toselected ones of the actuating mechanisms based at least in part on apredetermined dispensation plan and a geospatial coordinate.
 30. Theparticulate delivery system of claim 15; and a first set ofparticulate-transporting lines, each of said selectively-poweredparticulate metering sections corresponding to a respective one of thefirst set of particulate-transporting lines.
 31. The particulatedelivery system of claim 30; and a second set ofparticulate-transporting lines, said second set ofparticulate-transporting lines being oriented below and in line with thefirst set of particulate-transporting lines.
 32. The particulatedelivery system of claim 30; an airflow generator in communication withthe first set of particulate-transporting lines so as to providepneumatic conveying of the particulate within theparticulate-transporting lines; and a first set of damper assemblies,each of which is associated with a respective one of theparticulate-transporting lines, each of said damper assemblies beingoperable to selectively restrict airflow within the respectiveparticulate-transporting line responsive to variations in metering ofparticulate to the respective particulate-transporting line.
 33. Theparticulate delivery system of claim 32, wherein disengagement of therotatable engagement and metering wheels of one of theselectively-powered particulate metering sections corresponds withrestriction of airflow within the respective particulate transportingline by the corresponding damper assembly.
 34. The particulate deliverysystem of claim 15, said selectively-powered particulate meteringsections being individually controllable so that material dispensationis variable from one selectively-powered particulate metering section toanother.